Communication pubs.acs.org/JACS
Polycyclic Aromatic Triptycenes: Oxygen Substitution Cyclization Strategies Brett VanVeller, Derek J. Schipper, and Timothy M. Swager* Department of Chemistry, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, United States S Supporting Information *
ABSTRACT: The cyclization and planarization of polycyclic aromatic hydrocarbons with concomitant oxygen substitution was achieved through acid catalyzed transetherification and oxygen-radical reactions. The triptycene scaffold enforces proximity of the alcohol and arene reacting partners and confers significant rigidity to the resulting π-system, expanding the tool set of iptycenes for materials applications.
P
olycyclic aromatic hydrocarbons (PAHs) have attracted considerable attention because of their potential for molecular electronics.1−5 Inherent to the structure of many PAHs is an overall planar topology, which is generally desired to create the highest π-orbital overlap and electron delocalization.5−7 A common method to access PAHs is by the intramolecular oxidative cyclodehydrogenation of adjacent phenylene vertices through the Scholl reaction8 (1→2). This chemistry has broad application because of its ability to form multiple bonds between unfunctionalized C−H bonds under mild conditions with relatively high efficiency. Indeed, 2D graphene nanoribbons up to 12 nm in length have been synthesized from preassembled frameworks.9 However, tolerance of heteroatoms, which can dramatically modify the electronic properties of PAHs,10 has proven a synthetic challenge.11−16 The rigid 3D structure of iptycene-derived scaffolds has proven to be an exceptionally versatile motif for creating high performance and new material properties.17,18 Recently, our group reported an efficient synthesis of 1,4-dibromotriptycene diols (TD, 3) through a Rh-catalyzed [2 + 2 + 2] cycloaddition.19,20 To expand the diversity of iptycene scaffolds for PAH applications, we envisioned 3 might be elaborated through Pd cross-coupling methods (3→4). The resulting extended π-system (4) bears close proximity to the TD hydroxyl group, enforced by the triptycene scaffold, affording the opportunity for cyclization reactions to create oxygen substituted PAHs (5). We recently demonstrated this principle for cyclization of alkyne π-systems to transition between two classes of conjugated polymer backbones.19 Herein, we report the extension of this principle for the cyclization and planarization of a variety of arene π-systems, through oxidative and nonoxidative methods, to give triptycene incorporated PAHs with oxygen heteroatom substituents (4→5). Further, the [2,2,2]-ring system on which the triptycene is based appears to confer considerable rigidity, resulting in extremely sharp © 2012 American Chemical Society
photophysical features, introducing a new aspect of iptycene structure for electronic material design. 3 provided a convenient branch point to explore the proposed cyclization through diversification using Pd-catalyzed Suzuki−Miyaura cross-coupling; thus, 6 was synthesized in excellent yield (Scheme 1). The Scholl reaction is generally thought to proceed through an aromatic cation,21−23 and we envisioned the proximal electron rich oxygen of the hydroxyl group might be coaxed into reaction with the oxidized arene. Unfortunately, under several Scholl-type oxidants (FeCl3,24,25 DDQ,22b,26 CuCl227,28), only starting material was isolated. Concurrently, we also tested conditions likely to generate an Ocentered radical28 (CeIV,29−32 Pb(OAc)4,33 CuII/S2O82− 34,35). Encouragingly, cerium ammonium nitrate produced small amounts of the half-cyclized intermediate, but the CuII/ S2O82− protocol gave the fully cyclized 7 in good yield with spot-to-spot conversion by TLC. The structure of 7 was unambiguously confirmed by X-ray crystallography (Figure 1). Reports of the CuII/S2O82− conditions have invoked both aromatic radical cations36 and O-centered radical mechanisms,34,35 but we believe the oxygen-radical hypothesis to be the dominant pathway for this system (vide inf ra). Received: February 24, 2012 Published: April 18, 2012 7282
dx.doi.org/10.1021/ja3018253 | J. Am. Chem. Soc. 2012, 134, 7282−7285
Journal of the American Chemical Society
Communication
Scheme 1. Oxidative Cyclization of Phenylene Substrates
Scheme 2. Acid Catalyzed Transetherification Cyclization
conditions have been shown to oxidize the benzylic position of appended alkanes,35 substituents relevant for PAH solubility. We were inspired by the acid catalyzed transetherification of 3-methoxythiophenes38 and synthesized 13 in a similar manner as for 12. In the context of 13, the rigid TD scaffold holds the alcohol in close proximity to the 3-position of the thiophene (Scheme 2). Thus, protonation of the thiophene ring with ptoluenesulfonic acid in refluxing toluene allowed for 6membered transition state attack, via a COMe+ oxonium resonance structure, and substitution of the TD alcohol at the thiophene 3-position to give the cyclized product 13 in high yield (spot-to-spot conversion by TLC). The cyclization was confirmed by X-ray crystallography (Figure 1). The acid catalyzed transetherification of 3-methoxythiophenes has largely been applied for the attachment of alkyl side chains. Its application for annulation and planarization of πsystems is rare.16 We envisioned this reaction might hold promise more generally as a strategy for electron rich, oxygensubstituted, phenyl systems. Such systems have been problematic for PAHs because they are prone to quinone formation under the Scholl conditions. Further, the largely hydrocarbon family of PAHs are generally tolerant of protic acid conditions. To this end, 3 was used to synthesize 15, which in the presence of acid in boiling mesitylene afforded 16 in excellent yield.39 Finally, the structure was confirmed by X-ray crystallography (Figure 1). The successful cyclization of both transetherification substrates (14 and 16) was marked by the removal of rotational disorder in their 1H NMR spectra (Figure 2). For 13 and 15, steric clash between the methyl ether and TD hydroxyl groups led to broadening of these signals and the aryl-H signals on the “wings” of the TD, possibly due to rotomers and intramolecular H-bonding. Upon cyclization and planarization, the rotational isomerism, in addition to the signals for the hydroxyl proton and methyl ether, was removed. The effects of the cyclization reaction on all of the π-systems under study were most distinctly visualized in their UV/vis and fluorescence signatures relative to their respective starting materials (Figure 3a−d). The absorbance maxima for each compound red-shifted by almost 100 nm after cyclization (reducing the Stokes shift, Table 1). This closing of the HOMO−LUMO gap is ascribed to the increased planarity and the presence of electron-rich O-donor atoms that raise the HOMO level. Additionally, distinctly sharper absorbance and emission features (vibrational fine structure) for each compound were also observed. Finally, as expected, there is an associated increase in fluorescence quantum yield for the
Figure 1. X-ray crystal structures of cyclized compounds.
We next applied these conditions to higher order π-systems (11). Compound 8, an intermediate in the synthesis of TDs,20 was further elaborated to 9 by a [2 + 2 + 2] cycloaddition with diphenylacetylene and Wilkinson’s catalyst. Application of the CuII/S2O82‑ conditions led to successful cyclization of the TD hydroxyl groups (10) as anticipated, but failed to convert 9 to a fully cyclized compound. This observation lends support to our oxygen-radical hypothesis for cyclization, as an arene centered cation might have led to a fully cyclized product by a Scholltype mechanism. Attempts to cyclize the remaining arenes with FeCl3 led to complex oligomeric mixtures (11) most likely coupled para to the installed oxygen following established Scholl reactivity for such compounds.23 The proposed structure 11 is based on UV/vis (see Figure 3b and associated text for explanation) and MALDI-TOF mass spectrometry. We also investigated the CuII/S2O82− conditions with thiophene derivatives (Scheme 2, 12 and 13). Initial progress was hampered due to rapid deboronation of 2-thiophene boronic acid derivatives under cross-coupling conditions. However, application of a recently developed Pd precatalyst from the Buchwald laboratory37 allowed for milder conditions and returned the desired product in excellent yield. Yet, application of the CuII/S2O82− conditions produced complex mixtures and insoluble material. These results indicated the conditions to be too harsh for more electron rich aromatics. Further, we also desired a milder alternative as these oxidative 7283
dx.doi.org/10.1021/ja3018253 | J. Am. Chem. Soc. 2012, 134, 7282−7285
Journal of the American Chemical Society
Communication
Figure 2. 1H NMR comparison of (a) 13→14 and (b) 15→16. Signal assignments based on 1D coupling constants and 2D NMR experiments (see Supporting Information for further details).
cyclized products relative to their precursors (Table 1). These effects result from the removal of vibrational relaxation through planarization and the enforced rigidity of the [2,2,2] ring system of the triptycene scaffold. An exception to this is 16, which shows slightly broadened vibrational transitions likely due to rotational relaxation from the methoxy substituents. As mentioned above, the proposed structure of 11 is partially based on its absorbance spectrum (Figure 3b), which is indicative of a tribenzo[fg,ij,rst]pentaphene chromophore40 and supports the notion that portions of the oligomer are at least partially cyclized as 11 did show signs of electrochemical cyclization41 (see Supporting Information for further details). Cyclic voltammetry was used to investigate the redox behavior of the cyclized compounds (Figure 3e−h). Planarization and introduction of electron-donating O-atoms to the πsystems was anticipated to encourage oxidation by raising the HOMO level. This was indeed the case, as both 7 and 10 showed reversible oxidation peaks upon cyclization where 6 and 9 showed no redox behavior over the voltage scanned. Additionally, the more electron rich arenes in 14 and 16 showed two resolved single-electron oxidation peaks at lower potentials relative to 13 and 15 upon cyclization (Table 1). To summarize, we have developed a strategy that takes advantage of the surrounding molecular architecture for the enforced proximity of reacting partners. The cyclization
Figure 3. (a−d) UV/vis absorbance (solid) and fluorescence (dashed) spectra in CHCl3; (e−h) Cyclic voltammograms in CH2Cl2 with nBu4NPF6 as electrolyte (see Supporting Information for further details).
reactions succeed in the formation of low strain six-membered rings for extended planar PAHs with installed O-substituents and incorporated triptycene scaffolds. The triptycenes, in Table 1. Summary of Photophysical Data
6 7 9 10 11 13 14 15 16
abs λmaxa [nm]
em λmaxa [nm]
242 358 242 360 455b 275 384 302 380
363 359 387 465 407 386 375 388
log εb
ΦF
τF [ns]
Eoxc [V]
4.44 4.56 4.55 4.58
0.20 0.81
1.41 1.43
1.28
0.83 0.70 0.09 0.30 0.03 0.71
1.5 3.1 1.87 0.97 1.39 2.22
3.20 4.58 4.00 4.44
1.11 0.53 0.83/1.33 1.08 0.95/1.24
All values measured in CHCl3. bBased on red-most abs λmax. cAll values measured in CH2Cl2 with nBu4NPF6 as electrolyte. a
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Journal of the American Chemical Society
Communication
addition to fixing the hydroxyl group and arene into a favorable position, contribute significant rigidity to the resulting PAH. This effect on π-systems appears to be a design aspect not yet reported for 3D iptycene materials. While this strategy was demonstrated to work under oxidative conditions commonly employed for PAH syntheses, the preorganized framework also encouraged transetherification reactions with suitably functionalized arenes under Brønsted acid conditions. This acidcatalyzed mode of reactivity has not seen broad use in the field of PAH synthesis and might provide an avenue toward more heteroatom-substituted platforms. We hope to extend this strategy to other aromatic moieties and side chain functional groups.
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ASSOCIATED CONTENT
S Supporting Information *
Experimental protocols and analytical data. This material is available free of charge via the Internet at http://pubs.acs.org.
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AUTHOR INFORMATION
Corresponding Author
[email protected] Notes
The authors declare no competing financial interest.
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ACKNOWLEDGMENTS B.V. was supported by the Natural Science and Engineering Council of Canada (NSERC) and in part by an NIH BRP grant (R01 AG026240-01A1). D.J.S. was supported by an NSERC Postdoctoral Fellowship. This work was supported in part by the Air Force Office of Scientific Research (FA9550-10-10395). We thank Dr. Yu Lin Zhong for assistance with electrochemical measurements and Dr. Michael Takase for Xray crystal structures.
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